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What are Trigonometry Functions?
Trigonometry functions define the relationships among angles and sides of a right-angled triangle. The applications of such functions are wide-ranged and may be seen within the solutions of functional equations and differential equations. For instance, the sum and difference of trigonometric identities can be represented in any periodic process.
There are 6 trigonometric functions and they are as follows.
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sine
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cosine
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tangent
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cotangent
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secant
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cosecant
All the functions mentioned above also have corresponding inverse trigonometric functions.
Different Trigonometric Identities
Before proceeding with the sum and difference of trigonometric identities, let us go through some of the important identities.
Relations Between tan, cot, sec and cosec with Respect to sin and cos
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tan [theta] = [frac{sin theta}{cos theta}] cot [theta] = [frac{1}{tan theta}] = [frac{cos theta}{sin theta}] sec [theta] = [frac{1}{cos theta}] csc [theta] = [frac{1}{sin theta}] |
Relation Among sin and cos
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sin[^{2}][theta] + cos[^{2}][theta] = 1 |
Negative Angles Identities
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sin(-θ) = – sin θ cos(-θ) = cos θ tan(-θ) = – tan θ |
It can be seen from the identities that sin, tan, cot, and cosec amount to odd functions. On the other hand, sec and cos amount to even functions.
Sum Difference Angles Trigonometry – What are the Angle Identities?
The angle difference identities and sum identities are used to determine the function values of any of the angles concerned. To that effect, finding an accurate value of an angle may be represented as difference or sum by using the precise values of cosine, sine, and tan of angles 30°, 45°, 60°, 90°, 180°, 270°, and 360° as well as their multiples and sub-multiples.
The following table shows the sum and difference of trigonometric identities.
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Sum of Angles Identities |
Difference of Angles Identities |
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sin(A + B) = sin A . cos B + cos A . sin B |
sin(A – B) = sin A . cos B – cos A . sin B |
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cos(A + B) = cos A . cos B – sin A . sin B |
cos(A – B) = cos A . cos B + sin A . sin B |
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tan(A+B) = [frac{tanA+tanB}{1-tanA.tanB}] |
tan(A-B) = [frac{tanA-tanB}{1+tanA.tanB}] |
Converting Product to Sum and Difference of Trigonometric Identities
For deriving the relationship between sum and difference with that of the product of trigonometric identities compound angles have to be utilized. Below are some of the important relations.
sin (A + B) = sin A cos B + cos A sin B ………………………………… (1)
sin (A – B) = sin A cos B – cos A sin B …………………………………. (2)
cos (A + B) = cos A cos B + sin A sin B ………………………………… (3)
cos (A – B) = cos A cos B – sin A sin B …………………………………. (4)
Therefore, for the calculation of the product formula, it may be derived –
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2sin A cos B = sin (A + B) + sin (A – B)
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2sin A sin B = cos (A – B) – cos (A + B)
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2cos A sin B = sin (A + B) – sin (A + B)
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2cosA cos B = cos (A + B) + cos (A – B)
In deriving the formulas of the products, the conversion to sum and difference of trigonometric identities can also be done.
Few Solved Examples
1. Value of sin 15° with Help of Difference Formula
First step: sin (A – B) = (sin A X cos B) – (cos A X sin B)
Second step: sin (45 – 30) = (sin 45 X cos 30) – (cos 45 X sin 30)
By substituting the respective values, sin 15° comes to: [frac{sqrt{6}-sqrt{2}}{4}]
2. Value of cos 75° with Help of Sum Formula
First step: cos (A + B) = (cos A X cos B) – (sin A X sin B)
Second step: cos (30 + 45) = (cos 30 X cos 45) – (sin 30 X sin 45)
By substituting the respective values, cos 75° comes to: [frac{sqrt{6}-sqrt{2}}{4}]
The following points should be noted while solving these sums –
For further elaboration and clarification on the topic, you may avail of ’s online classes or download the free PDFs on sums from trigonometric identity from .
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